EA004407B1 - Retrieving a sample of formation fluid in a cased hole - Google Patents

Abstract

1. A method of retrieving a sample of formation fluid from a formation layer traversed by a cased borehole comprising the steps of: a) making a plurality of perforation sets through the casing wall into the formation layer, wherein the orientation of the perforation sets is so selected that the angle between adjacent perforation sets equals 360 degree divided by the number of perforation sets; b) lowering a sampling tool into the borehole to the first perforation set, which sampling tool comprises a central conduit having an inlet and a discharge, several fluid sample containers opening into the central conduit, and a system for discharging fluids from the central conduit and for moving fluids into the fluid sample containers, which sampling tool is provided with an upper and a lower packer arranged at either side of the inlet of the central conduit, wherein the discharge opens above the upper packer or below the lower packer, wherein the distance between the upper and the lower packer is larger than the height of a perforation set, wherein the length of the longest packer is smaller than the spacing between adjacent perforation sets; c) setting the packers so that the perforation set is straddled between the packers, taking a sample from the formation, storing the sample in the first fluid sample container and shutting off the first fluid sample container; d) positioning the sampling tool near the next perforation set, setting the packers so that the perforation set is straddled between the packers, taking a sample from the formation, storing the sample in the next fluid sample container and shutting off the next fluid sample container; and e) repeating step d) until samples from at most all perforation sets have been taken, and retrieving the sampling tool. 2. The method according to claim 1, wherein step d) is repeated until samples from all perforation sets have been taken. 3. The method according to claim 1, wherein the sampling tool further comprises a fluid analyser, and wherein step d) is repeated until formation fluid is detected. 4. The method according to any one of claims 1-3, wherein the lowermost perforation is marked, and the sampling tool comprises a device for detecting the marker. 5. The method according to claim 4, wherein the marker is a radioactive tracer, and wherein the sampling tool comprises a nuclear tool for detecting the radioactive tracer. 6. The method according to claim 5, wherein the nuclear tool is a gamma ray detector.

Description

The present invention relates to sampling formation fluid from a layer of a formation through which a cased well passes. The reservoir may be petroleum or such a reservoir, which is assumed to contain hydrocarbons.

A cased well is a well lined with a casing string that is cemented into the well so that the annular annular gap between the outer surface of the casing and the inner surface of the cased well is filled with hardened cement. The cased well is filled with fluid used to displace the cement from the well into the annular space before the cement hardens. The fluid that fills the cased hole is so dense that fluids cannot flow into the well.

For sampling fluid from the reservoir, the wall of the casing string is perforated at a site of a certain length within the thickness of the reservoir. The tool used to form the perforations is a downhole perforator. It is an oblong body, equipped with a set of outward charges. The charges are located along the body of the perforator in different places, oriented in different directions, and can be actuated electrically or mechanically. The charges are made in such a way that, when fired, each charge in the casing produces a perforation hole that passes through the wall of the casing to the rock surrounding the cased well. A downhole perforator can be lowered into a cased well using, for example, a pulley rope.

To obtain a sample of fluid, a perforator is lowered to a certain depth and the charges are activated for punching a plurality of perforations. At the same time, the entry of formation fluid into the casing string prevents the fluid inside it.

Then the sampler is lowered into the cased well with, for example, a pulley rope. The sampler contains an inner central channel having an inlet and an outlet, a container for fluid sample communicating with the central channel, and a device for draining fluids from the central channel and feeding them into the container for fluid sample. The sampler is also equipped with upper and lower packers installed on each side of the inlet of the central channel, the outlet in which opens below the lower packer. The distance between the upper and lower packers is greater than the height of the perforations.

The sampler is arranged in such a way that the upper packer is placed above the perforations, and the lower packer is located below the perforations. Then the packers are installed so as to seal the sample-receiving chamber formed between the packers, with which (with the camera) all the perforations communicate.

A system for discharging fluids from the internal channel and for supplying fluids to the sample container includes a pump. The pump is pre-activated to remove liquid from the sample collection chamber. The time required to remove fluid from the chamber is equal to the volume of the chamber divided by the amount of flow created by the pump.

The pump is then re-activated, with the fluid flowing into the central internal channel being fed to the container for the sample to be taken. When the sample container is full, it is tightly closed, and the sampler is removed from the cased well.

On the surface (ground) the container with the sample is transferred to the laboratory for subsequent analysis of the sample. This analysis is important because it answers the question of whether or not the formation fluid contains a valuable hydrocarbon.

Unfortunately, the fluid selected for analysis is not always necessarily a formation fluid. For example, when the cement in the annular gap does not completely fill this gap, in this case a channel with low flow resistance is formed. As a result, fluids from this channel will be sucked into the sample chamber.

The present invention is to eliminate this drawback and the provision of a method for obtaining a sample of fluid, which uniquely represents a reservoir fluid.

To solve this problem, the proposed method of sampling formation fluid from a layer of a reservoir traversed by a cased well, in accordance with the present invention includes the following stages:

a) the formation of a large number of rows of perforations that pass through the wall of the casing into the formation layer, and the arrangement of the rows of perforations is chosen such that the angle between adjacent rows of perforations is equal to the partial number of perforations by dividing the angle;

b) immersing the sampler in a cased well up to the first row of perforations, the sampler comprising an internal channel having inlet and outlet, sample containers of various fluids communicating with the internal channel, and a system for releasing fluids from the internal channel and for supplying them to sample containers, the sampler provided with upper and lower packers installed on each side of the entrance to the central internal channel, the release is communicated with the area above the upper packer or below the lower packer, the distance between the upper and lower packers exceeds the height of the number of perforations, the length of the longest packer is less than the gap (in height) between adjacent perforations;

c) installing the packers so that one row of perforations is enclosed between the packers, taking a sample from the formation, filling the sample with the first container and sealing the first container with the sample of the fluid;

b) placing the sampler near the next row of perforations, installing the packers so that the next row of perforations is between packers, taking a sample from the reservoir, filling the sample with the next fluid container, and sealing the next fluid sample container;

e) repeating stage b) until samples have been taken from almost all the rows of perforations and removing the sampler.

In the description and the claims of the present invention, the concept of a series of perforations implies the presence of at least one perforation hole, and if there are two or more perforations in the row of perforations, they are oriented in the same way.

The method for sampling formation fluid from a reservoir intersected by a cased well in accordance with this invention will be described in more detail below.

To obtain samples from the formation fluid, the casing is perforated. In accordance with the present invention, perforating a casing includes making a plurality of rows of perforations passing through the wall of the casing into a formation layer. The height of each row of perforations is less than the distance between the upper and lower packers of the sampler, and the distance between adjacent rows of perforations is at least equal to the length of the longest packer of the sampler. When placing the sampler at the sampling site, the specified ratio of sizes provides an overlap of the volume for sampling formed between the packers of one and only one row of perforations.

In addition, the mutual arrangement of the rows of perforations is chosen in such a way that the angle between the adjacent rows of perforations is equal to the ratio of the magnitude of 360 ° to the number of rows of perforations. Due to this arrangement, the samples to be sampled are located along the perimeter of the casing circumference, and a separate sample can be taken from a certain separate direction and at a different level along the formation height. Thus, the likelihood that all samples will be contaminated is negligible. Contamination of the sample is possible, for example, if there is no cement behind the casing.

Next, for sampling, the sampler is lowered into the cased well to the first, lowest row of perforations. The sampler contains a central channel with an inlet and an outlet, several containers for sampling fluids, the containers communicating with the central channel, and a device for discharging fluids from the central channel and delivering them to the containers for sampling fluids. In addition, the sampler is equipped with upper and lower packers installed on each side of the entrance to the central channel. The release from the center channel communicates with the area above the upper packer or below the lower packer. The location of the release depends on the design of the sampler, but it should be located outside the chamber from which a sample is taken located between the packers.

The sampler may, for example, be lowered down with a pulley rope.

Packers are installed so that a number of perforations are enclosed between the upper and lower packers. In this way, the sampling site is cut off from the rest of the casing. The fluids are sucked into the central channel and are released from it until the entire displaced volume of the space for the selection is replaced by fluids. Then a sample is taken from the formation and fed to the first container for fluid sample. When the first container is filled with the sample, it is sealed. Sampling may be preceded by the release of the contents of the space intended for sampling to the area below the lower packer.

After taking the first sample, the sampler is placed near the next upstream row of perforations. Packers are installed so that this series of perforations is enclosed between the packers. The sample is taken from the reservoir and loaded into the next container, after which this next container is isolated.

The last stage is repeated until samples are taken from almost all rows of perforations. The sampler is removed from the cased well.

On the surface (ground), containers with fluid samples are removed from the sampler, and the contents of these containers are analyzed in the laboratory in order to obtain the necessary information.

It is possible that the sampling stage from the next row of perforations is repeated until samples are taken from all the rows of perforations.

In an alternative embodiment of the present invention, the sampler further comprises a fluid analyzer. The sampling step from the next row of perforations is repeated until the formation fluid is detected.

For example, it is necessary to take samples from a 40-meter-thick layer of sand through a cased hole, a passing layer of sand of such thickness. The height of a row of perforations is 0.5 m, and the distance between adjacent rows of perforations is 1.5 m. Therefore, the number of rows of perforations is 20 (= 40 / (0.5 + 1.5), while the angle (along the perimeter of the pipe circumference) between the two adjacent rows of perforations is 18 ° (= 360 ° / 20). The packer installed on the sampler is about 0.5 m, which is less than the specified interval of 1.5 m, and the distance between the nearest ends of the packer is 1.5 m. In this case, the sampler should contain at most 20 containers for fluid samples.

Preferably, the lowest perforation is labeled, and the sampler comprises means for indicating the label. The label preferably serves as a radioactive isotope, and the sampler is equipped with a radiation instrument for detecting a radioactive isotope. It is preferable to use a gamma radiation detector as a radiation instrument.

The present invention provides a simple method that ensures that at least one of the samples taken is definitely a sample of a formation fluid.

Claims (6)

CLAIM 1. The method of sampling formation fluid from the layer of the reservoir through which the cased well passes, which includes the following stages: a) the formation of multiple rows of perforations in the wall of the casing, with the arrangement of rows of perforations chosen so that the angle between adjacent rows of perforations is equal to the quotient from the division of an angle of 360 ° by the number of rows of perforations; b) lowering the sampler into the cased well to the first row of perforations, the sampler contains an internal channel having inlet and outlet, several containers for fluid samples communicating with the internal channel, and a system for releasing fluids from the internal channel and feeding them into containers for samples and also provided with upper and lower packers installed on each side of the entrance to the central internal channel, the release communicates with the area above the upper packer or below the lower pack pa, the distance between the upper and lower packers exceeds the height of the number of perforations, and the length of the longest packer is less than the gap between adjacent rows of perforations; c) installing the packers so that one row of perforations is enclosed between the packers, taking a sample from the formation, filling the sample with the first container and sealing the first container with the sample of the fluid; b) placing the sampler near the next row of perforations, installing the packers so that the next row of perforations is between packers, taking a sample from the reservoir, filling the sample with the next container and sealing the next container with the sample fluid; e) repeating stage b) until samples are taken from almost all the rows of perforations, and the sampler is removed. 2. The method in accordance with claim 1, characterized in that stage b) is repeated until samples from all rows of perforations are taken. 3. The method according to claim 1, characterized in that the sampler also includes a fluid analyzer, as well as the fact that stage b) is repeated until the formation fluid is detected. 4. The method according to any one of claims 1 to 3, characterized in that the lowermost perforation is provided with a label, and the sampler is equipped with a device for detecting the label. 5. The method according to claim 4, characterized in that a radioactive isotope is used as the label, and the sampler is equipped with a radiation instrument for detecting the presence of a radioactive isotope. 6. The method according to claim 5, characterized in that the gamma-radiation detector is used as a radiation instrument.